Wireless local area network receiver and associated method

ABSTRACT

A wireless local area network (WLAN) includes a server and receiver, which includes a radio frequency (RF) front-end circuit that receives wireless signals from the mobile nodes within the WLAN and detects baseband signals. A signal waveform detector edge detects a signal waveform and generates a trigger signal indicative of the modulation type, data format and time-of-arrival (TOA) information of a desired signal to be captured. A baseband processor receives the trigger signal from the signal waveform detector and captures the desired signal. A system controller is connected to the baseband processor and configures the baseband processor for processing the desired signal and obtaining message data and signal metrics that are transferred to the system controller to be communicated outbound from the receiver as a client to the server.

CROSS-REFERENCE TO RELATED APPLICATION

This application is a continuation of U.S. application Ser. No. 11/692,250, filed on Mar. 28, 2007; which claims priority to U.S. Provisional Application Ser. No. 60/787,885, filed on Mar. 31, 2006, each of which are hereby incorporated herein in their entirety by reference.

FIELD OF THE INVENTION

This invention relates to the field of wireless local area networks (WLAN's), and more particularly, this invention relates to real-time location systems and WLAN's.

BACKGROUND OF THE INVENTION

Wireless local area networks (WLAN) and real-time location systems (RTLS) are becoming more commonplace as the use of portable computers, such as “laptop,” “notebook,” and “pen” computers become increasingly common in office environments and other locations. Examples of real-time location systems and the circuitry and algorithms used in such real-time location systems are described in commonly assigned U.S. Pat. Nos. 5,920,287; 5,995,046; 6,121,926; and 6,127,976, the disclosures which are hereby incorporated by reference in their entirety. Examples of real-time location systems that are operative with wireless local area networks are disclosed in commonly assigned U.S. Pat. Nos. 6,892,054; 6,987,744; 7,046,657; and 7,190,271, the disclosures which are hereby incorporated by reference in their entirety.

It is desirable in some WLAN systems if a real-time location system can incorporate a receiver that connects to a network as a client, which is simple, and incorporates existing information technology (IT) communications systems, and could be used in conjunction with an access point or alone, and provide some ability to locate access points and communicate to a server.

BRIEF SUMMARY

A wireless local area network (WLAN) includes a server and receiver in communication with the server as a network client. The receiver includes a radio frequency (RF) front-end circuit that receives wireless signals from the mobile nodes within the WLAN and detects baseband signals. A signal waveform detector is connected to the RF front-end circuit for edge detecting a signal waveform and generating a trigger signal indicative of the modulation type, data format and time-of-arrival (TOA) information of a desired signal to be captured. A baseband processor is connected to the RF front-end circuit and the signal waveform detector and receives the trigger signal from the signal waveform detector and captures the desired signal. A system controller is connected to the baseband processor and configures the baseband processor for processing the desired signal and obtaining message data and signal metrics that are transferred to the system controller to be communicated outbound from the receiver to the server.

A media access control (MAC) device is connected between the system controller and server. A TOA processor is connected to the baseband processor and receives the TOA information and generates the time stamp for the desired signal. In this non-limiting example, the TOA processor can be operative for processing TOA information when the receiver is part of a geometric array of network nodes and determine first-to-arrive signals based on a common network timing signal and conduct differentiation of the first-to-arrive signals to locate a desired wireless node.

In yet another aspect, a wireless network connection exists between the server and the receiver. In still another aspect, a wired network connection exists between the server and the receiver.

It is possible to have diversity antennas connected to the RF front-end circuit and provide spatial diversity. The system controller can be operative for controlling RF signal selection to dual RF channels connected to the diversity antennas. A wireless access point is connected to the receiver. A multiplexer switch can be connected between the receiver and the wireless access point for selectively switching between the receiver and the wireless access point.

A method aspect is also set forth.

BRIEF DESCRIPTION OF THE DRAWINGS

Other objects, features and advantages of the present invention will become apparent from the detailed description of the invention which follows, when considered in light of the accompanying drawings in which:

FIG. 1 is a block diagram of a WLAN system showing basic components of a WLAN receiver in accordance with a non-limiting example of the present invention.

FIG. 2 is a block diagram of an example of a diversity antenna for the receiver in accordance with a non-limiting example of the present invention.

FIG. 3 is a block diagram of an active antenna for the receiver in accordance with another non-limiting example of the present invention.

FIG. 4 is a high-level block diagram of one example of the circuit architecture that can be modified for use as part of a processor for determining first-to-arrive signals.

FIG. 5 is another high-level block diagram of an example of the circuit architecture that can be used as modified for correlation-based signal processors.

DETAILED DESCRIPTION

The present invention will now be described more fully hereinafter with reference to the accompanying drawings, in which preferred embodiments of the invention are shown. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. Like numbers refer to like elements throughout, and prime notation is used to indicate similar elements in alternative embodiments.

In accordance with a non-limiting example of the present invention, a WLAN system includes a receiver that is connected to a network as a client. It is usable as a “soft” (modular and software upgradable) location processor system for different types of wireless signal formats and frequencies or combinations. It could be operative as a system for locating WLAN terminals and tag transmitter location, for example, operative with Wherenet ISO24730 devices.

Low complexity and simplicity of operation with existing information technology communications networks is provided. The receiver can be operative as an active antenna and can isolate the real-time location system (RTLS) layer from the network and allow upgrades for more flexibility. It can comply with existing and evolving network security processes by having the receiver operate as a client and not as an access point (AP). The receiver can lower the cost of a real-time location system detection in a physical layer. The receiver can be remotely set to modulation formats and frequencies that are completely independent of a host access point.

A receiver for use in the illustrated WLAN system, in accordance with a non-limiting example of the present invention, is shown in FIG. 1 at 10. The RF antenna 12 can be a single frequency or multi-band antenna. Various other wireless nodes are illustrated as part of the WLAN. A configurable RF front-end circuit 14 can also be single frequency or multi-band for receiving multiple frequencies. The RF front-end circuit 14 is configured for baseband detection 16, which can be either a full or partial bandwidth to constrain the number of detected signals.

A configurable signal waveform detector 18 can be remotely set for initial edge detection of a desired signal waveform (or waveforms) to be processed. A trigger signal is generated at 20 to a baseband processor 22 for the desired signal and modulation type, data format and time-of-arrival (TOA) capture configurations. This trigger signal is generated for each desired signal to be captured. The baseband processor 22 is operative at a real-time configuration and detects the desired signal waveform and data. This baseband processor 22 can support multiple waveform types and the signal capture can be a priori to trigger generation. The waveform capture occurs in real-time during the trigger signal generation.

As illustrated, the detected signal waveform capture can either be sent to the system controller 26 for communication to a remote time-of-arrival (TOA) processor, or an on-board TOA processor 28 can produce a time stamp for arrival of the captured signal. The time-of-arrival information can be sent to the system controller 26. The message data and signal metrics can be sent to the system controller 26, which can manage both the real-time configuration of the receiver 10 and the data to be communicated outbound through the media access controller (MAC) device 34 to a server 36. The illustrated receiver 10 would include its own MAC address.

At the RF front-end 14, the signal waveform detector 18 and baseband processor 22 can be real-time preconfigured by the system controller, based on locally generated and remote system requirement-based instructions. The MAC device 34 directs data, as a client, through either a wired or wireless connection, to the host network.

It should be understood that the configurable signal waveform detector 18 can be formed as a number of detectors that are used for detecting a number of desired signal waveforms. The system controller can also feedback specific signal mode and location asset identifier (ID) commands to the baseband processor that works in conjunction with the TOA processor 28 for determining asset locations such as a wireless node 11.

FIG. 2 shows two antennas 50,52 operative with the receiver 10, which could include a dual channel processor indicated at 54. Antenna special diversity is provided. The processor 54 can be incorporated into the RF front-end circuit 14 or part of the baseband processor 22. The two antennas 50,52 can be spaced apart to provide spatial diversity. The processor 54 can be configured with a common signal processor and RF signal strength based selection of two RF front-end channels. It is also possible to configure two completely separated detection channels that are controlled by the system controller.

As shown in FIG. 3, an active antenna system for a WLAN access point is illustrated. Two antennas 60,62 are illustrated and connected to a radio frequency multiplexer 64 operative as a switch that connects into the dual channel processor 54, which could be similar to the processor shown in FIG. 2, and a WLAN access point 66. The RF multiplex switch (MUX) 64 simultaneously receives RF signals for transmission to the receiver 10 and host WLAN access point 66 as selected. The switch 64 selects between the two “clients” for RF transmission. This active antenna device can connect to the access point 66 as a replacement for its normal passive antenna and interfaces to a host access point as a wireless client. The circuit can include a preamplifier or RE line amplifier or other component for an active antenna circuit.

There are various advantages of the receiver 10 as described. These advantages include connectivity to an information communications network as a client of that network, either wireless or wired. The receiver 10 can be combined with an antenna as a location processor such as described in the incorporated by reference patents and connect as a network client. It is also possible to use the device either as a replacement for an external antenna of a wireless network access point (AP) or as an independently located client.

It is also possible to direct remotely the receiver as an element of a geometric array for locating an asset such as an RF tag or wireless network client. It is also possible to reconfigure remotely in real-time the receiver for a center RF receive frequency and RF and information bandwidth. The receiver 10 can detect a desired signal format and select a desired signal for detection and processing based on specific data in the detected signal packet and/or data format such as a client ID, asset category, packet length and similar details. The receiver can be operative as a system engine capable of detecting multiple modification formats and RF frequencies in the order of incoming reception and according to a remote preset, such as the priority of signal type and the frequency and the priority of signal ID.

For purposes of description, the type of location circuits, algorithm, and associated functions that can be modified for use with the present invention are set forth in the incorporated by reference patents. For purposes of description, FIGS. 4 and 5 describe representative examples of circuit architectures that can be modified for use, in accordance with non-limiting examples of the present invention, and used in the receiver 10 architecture associated therewith.

FIG. 4 diagrammatically illustrates one type of circuitry configuration of a respective location receiver (or “reader”) architecture for “reading” location pulses or associated signals, “blink” as sometimes referred, such as emitted from a mobile station. An antenna 210 senses appended transmission bursts or other signals from a respective mobile station. The antenna, which could be omnidirectional and circularly polarized, is coupled to a power amplifier 212, whose output is filtered by a bandpass filter 214. Respective I and Q channels of the bandpass filtered signal are processed in associated circuits corresponding to that coupled downstream of filter 214. To simplify the drawing, only a single channel is shown.

A respective bandpass filtered I/Q channel is applied to a first input 221 of a down-converting mixer 223. Mixer 223 has a second input 225 coupled to receive the output of a phase-locked local IF oscillator 227. IF oscillator 227 is driven by a highly stable reference frequency signal (e.g., 175 MHz) coupled over a (75 ohm) communications cable 231 from a control processor. The reference frequency applied to phase-locked oscillator 227 is coupled through an LC filter 233 and limited via limiter 235.

The IF output of mixer 223, which may be on the order of 70 MHz, is coupled to a controlled equalizer 236, the output which is applied through a controlled current amplifier 237 and applied to communications cable 231 to a communications signal processor, which could be an associated processor 32,32 a. The communications cable 231 also supplies DC power for the various components of the location receiver by way of an RF choke 241 to a voltage regulator 242, which supplies the requisite DC voltage for powering an oscillator, power amplifier and analog-to-digital units of the receiver.

The amplitude of the (175 MHZ) reference frequency supplied by the communications control processor to the phase locked local oscillator 227 implies the length of any communications cable 231 (if used) between the processor and the receiver. This magnitude information can be used as control inputs to an equalizer 236 and current amplifier 237, so as to set gain and/or a desired value of equalization, which may be required to accommodate any length of a communication cable. For this purpose, the magnitude of the reference frequency may be detected by a simple diode detector 245 and applied to respective inputs of a set of gain and equalization comparators shown at 247. The outputs of comparators are quantized to set the gain and/or equalization parameters.

FIG. 5 illustrates the architecture of a correlation-based, RF signal processor as part of processor to which the output of a respective RF/IF conversion circuit of FIG. 4 can be coupled for processing the output and determining location. The correlation-based RF signal processor correlates spread spectrum signals detected by its associated receiver with successively delayed or offset in time (by a fraction of a chip) spread spectrum reference signal patterns, and determines which spread spectrum signal received by the receiver is the first-to-arrive corresponding to a “blink” or location pulse as part of the communications signal that has traveled over the closest observable path between a mobile station and a location receiver.

Because each receiver can be expected to receive multiple signals from the mobile station, due to multipath effects caused by the signal transmitted by the mobile station being reflected off various objects/surfaces between the mobile station and the receiver, the correlation scheme ensures identification of the first observable transmission, which is the only signal containing valid timing information from which a true determination can be made of the distance from the tag to the receiver.

For this purpose, as shown in FIG. 5, the RF processor employs a front-end, multi-channel digitizer 300, such as a quadrature IF-baseband down-converter for each of an N number of receivers. The quadrature baseband signals are digitized by associated analog-to-digital converters (ADCs) 272I and 272Q. Digitizing (sampling) the outputs at baseband serves to minimize the sampling rate required for an individual channel, while also allowing a matched filter section 305, to which the respective channels (reader outputs) of the digitizer 300 are coupled to be implemented as a single, dedicated functionality ASIC, that is readily cascadable with other identical components to maximize performance and minimize cost.

This provides an advantage over bandpass filtering schemes, which require either higher sampling rates or more expensive ADCs that are capable of directly sampling very high IF frequencies and large bandwidths. Implementing a bandpass filtering approach typically requires a second ASIC to provide an interface between the ADCs and the correlators. In addition, baseband sampling requires only half the sampling rate per channel of bandpass filtering schemes.

The matched filter section 305 may contain a plurality of matched filter banks 307, each of which is comprised of a set of parallel correlators, such as described in the above identified, incorporated by reference '926 patent. A PN spreading code generator could produce a PN spreading code (identical to that produced by the PN spreading sequence generator of the location transmitter). The PN spreading code produced by a PN code generator is supplied to a first correlator unit and a series of delay units, outputs of which are coupled to respective ones of the remaining correlators. Each delay unit provides a delay equivalent to one-half a chip. Further details of the parallel correlation are disclosed in the '926 patent.

As a non-limiting example, the matched filter correlators may be sized and clocked to provide on the order of 4×10⁶ correlations per epoch. By continuously correlating all possible phases of the PN spreading code with an incoming signal, the correlation processing architecture effectively functions as a matched filter, continuously looking for a match between the reference spreading code sequence and the contents of the incoming signal. Each correlation output port 328 is compared with a prescribed threshold that is adaptively established by a set of ‘on-demand’ or ‘as needed’ digital processing units 340-1, 340-2, . . . , 340-K. One of the correlator outputs 328 has a summation value exceeding the threshold, which delayed version of the PN spreading sequence is effectively aligned (to within half a chip time) with the incoming signal.

This signal is applied to a switching matrix 330, which is operative to couple a ‘snapshot’ of the data on the selected channel to a selected digital signal processing unit 340-i of the set of digital signal processing units 340. The mobile station can ‘blink’ or transmit location pulses randomly, and can be statistically quantified, and thus, the number of potential simultaneous signals over a processor revisit time could determine the number of such ‘on-demand’ digital signal processors required. A processor would scan the raw data supplied to the matched filter and the initial time tag. The raw data is scanned at fractions of a chip rate using a separate matched filter as a co-processor to produce an auto-correlation in both the forward (in time) and backwards (in time) directions around the initial detection output for both the earliest (first observable path) detection and other buried signals. The output of the digital processor is the first path detection time, threshold information, and the amount of energy in the signal produced at each receiver's input, which is supplied to and processed by the time-of-arrival-based multi-lateration processor section 400.

As a non-limiting example, the processor section 400 can use a standard multi-lateration algorithm that relies upon time-of-arrival inputs from at least three detectors to compute the location of the object. The algorithm may be one which uses a weighted average of the received signals. In addition to using the first observable signals to determine object location, the processor also can read any data read out of a mobile station's memory and superimposed on the transmission. Object position and parameter data can be downloaded to a database where object information is maintained. Any data stored in a mobile station memory may be augmented by altimetry data supplied from a relatively inexpensive, commercially available altimeter circuit. Further details of such circuit are disclosed in the '926 patent.

It is also possible to use an enhanced circuit as disclosed in the '926 patent to reduce multipath effects, by using dual antenna and providing spatial diversity-based mitigation of multipath signals. In such systems, the antennas of each location receiver are spaced apart from one another by a distance that is sufficient to minimize destructive multipath interference at both antennas simultaneously, and also ensure that the antennas are close enough to one another so as to not significantly affect the calculation of the location of the object by the downstream multi-lateration processor.

The multi-lateration algorithm executed by the processor is modified to include a front-end subroutine that selects the earlier-to-arrive outputs of each of the detector pairs as the value to be employed in the multi-lateration algorithm. A plurality of auxiliary ‘phased array’ signal processing paths can be coupled to the antenna set (e.g., pair), in addition to the paths containing the directly connected receivers and their associated first arrival detector units that feed the triangulation processor. Each respective auxiliary phased array path is configured to sum the energy received from the two antennas in a prescribed phase relationship, with the energy sum being coupled to associated units that feed a processor as a triangulation processor.

The purpose of a phased array modification is to address the situation in a multipath environment where a relatively ‘early’ signal may be canceled by an equal and opposite signal arriving from a different direction. It is also possible to take advantage of an array factor of a plurality of antennas to provide a reasonable probability of effectively ignoring the destructively interfering energy. A phased array provides each site with the ability to differentiate between received signals, by using the ‘pattern’ or spatial distribution of gain to receive one incoming signal and ignore the other.

The multi-lateration algorithm executed by the processor could include a front-end subroutine that selects the earliest-to-arrive output of its input signal processing paths and those from each of the signal processing paths as the value to be employed in the multi-lateration algorithm (for that receiver site). The number of elements and paths, and the gain and the phase shift values (weighting coefficients) may vary depending upon the application.

It is also possible to partition and distribute the processing load by using a distributed data processing architecture as described in the incorporated by reference U.S. Pat. No. 6,127,976. This architecture can be configured to distribute the workload over a plurality of interconnected information handling and processing subsystems. Distributing the processing load enables fault tolerance through dynamic reallocation.

The front-end processing subsystem can be partitioned into a plurality of detection processors, so that data processing operations are distributed among sets of detection processors. The partitioned detection processors can be coupled in turn through distributed association processors to multiple location processors. For maximum mobile station detection capability, each receiver is preferably equipped with a low cost omnidirectional antenna that provides hemispherical coverage within the monitored environment.

A detection processor filters received energy to determine the earliest time-of-arrival energy received for a transmission, and thereby minimize multi-path effects on the eventually determined location of a mobile device. The detection processor can demodulate and time stamp all received energy that is correlated to known spreading codes of the transmission, so as to associate a received location pulse with only one mobile station. It then assembles this information into a message packet and transmits the packet as a detection report over a communication framework to one of the partitioned set of association processors, and then de-allocates the detection report.

A detection processor to association control processor flow control mechanism can equitably distribute the computational load among the available association processors, while assuring that all receptions of a single location pulse transmission, whether they come from one or multiple detection processors, are directed to the same association processor.

The flow control mechanism can use an information and processing load distribution algorithm, to determine which of the association processors is to receive the message, and queues the message on a prescribed protocol coupling socket connecting the detection processor to the destination association processor. To select a destination association processor, the information and processing load distribution algorithm may include a prime number-based hashing operation to ensure a very uniform distribution of packets among association processors. In addition, to provide relatively even partitioning in the case of widely varying transmission rates, the hashing algorithm may use a sequence number contained in each transmission.

Each association processor can organize its received message packets by identification (ID) and time-of-arrival (TOA), and stores them as association reports. The association processor compresses the data within the association report, transmits that information over an association communication process of the communication framework to one of a plurality of distributed location processors, and then de-allocates the association report.

In order to deliver all association reports that have been generated for an individual mobile station (or device) to a single destination location processor, the association communication process of the communication framework may employ the same information and processing load distribution algorithm executed by the detection communication process of the communication framework. Each location processor determines the geographical location of a mobile station using the time-of-arrival measurement information originally sourced from the detection processors. The specific algorithm employed for location determination matches the number of arrival time measurements with whatever a priori information is available.

To locate a mobile station, a location processor may employ all available diversity information associated with the mobile station of interest, including, but not limited to the mobile station ID, any data contained in the transmission and metrics indicating confidence in these values. It then forwards a location report containing this information over a location communication process to an asset management database. A location estimate may be derived from the measured time-of-arrival information in a received association report packet, using a differential time-of-arrival algorithm, such as a hyperbolic geometry-based function.

It is also possible to use a wireless local area network (WLAN) spread spectrum waveform to perform the geo-location function of the present invention. The assumption is that the wireless communications signal, as a spread spectrum signal, has a high signal-to-noise ratio with reasonable power levels. The leading edge of this communication signal can be detected to a high accuracy and this information used with the algorithms as described before to provide relative time of arrival information for subsequent processing. It is also possible to have a timing signal from a known location. Other component locations would have to be known, of course. For example, some wireless local area network (WLAN) transmitters have known locations to enable the use of the algorithm when an access point base station or mobile station location is known.

It is also known that the communications signal as a spread spectrum communications signal can have sufficient bandwidth to provide useful time accuracy. For example, a 50 MHz bandwidth could provide approximately 5 nanoseconds of timing accuracy that is about 5 feet of accuracy using much of the technology and teachings described before. It is possible to use a correlator operative as a functional spread spectrum matched filter to enable a higher quality estimate with integration over many chips of the spread spectrum transmission. It is possible to use a matched filter that spans multiple symbols and improve accuracy by collecting more energy in the filter prior to leading edge detection.

Many modifications and other embodiments of the invention will come to the mind of one skilled in the art having the benefit of the teachings presented in the foregoing descriptions and the associated drawings. Therefore, it is understood that the invention is not to be limited to the specific embodiments disclosed, and that modifications and embodiments are intended to be included within the scope of the appended claims. 

1. A wireless local area network comprising: a server; and a device comprising: a real time location system receiver radio frequency front-end circuit that receives wireless signals from mobile nodes within the wireless local area network; a processor that processes the received signals and obtains message data and signal metrics including time-of-arrival information; a wireless local area network access point comprising a processor and circuitry configured to: provide connections to the wireless local area network for a plurality of wireless devices; and send the message data and signal metrics to a server.
 2. The wireless local area network of claim 1 wherein the device is configured to receive signals in multiple frequency bands wherein the real time location system receiver receives signals in at least a first frequency band and the wireless local area network access point receives signals in a second frequency band.
 3. The wireless local area network of claim 1 further comprising a time-of-arrival processor that generates a time stamp for the received signal.
 4. The wireless local area network of claim 3 wherein the time-of-arrival processor is operative for processing time-of-arrival information when said device is part of a geometric array of networked nodes and determining first-to-arrive signals based on a common network timing signal and conducting differentiation of the first-to-arrive signals to locate a desired wireless node.
 5. The wireless local area network of claim 1 wherein the real time location system receiver comprises an active antenna system of the wireless local area network access point.
 6. The wireless local area network of claim 4 wherein the wireless local area network access point is configured with the active antenna system instead of a passive antenna.
 7. (canceled)
 8. (canceled)
 9. (canceled)
 10. (canceled)
 11. An apparatus in a wireless local area network, comprising: a real time location system receiver; and a wireless local area network access point; the real time location system receiver comprising: a radio frequency front-end circuit that receives wireless signals from mobile nodes within the wireless local area network; and a processor that processes the received signals and obtains message data and signal metrics including time-of arrival in formation; the wireless local area network access point comprising a processor and circuitry configured to: provide connections to the wireless local area network for a plurality of wireless devices; and send the message data and signal metrics to a server.
 12. The apparatus of claim 11 wherein the device is configured to receive signals in multiple frequency bands wherein the real time location system receiver receives signals in at least a first frequency band and the wireless local area network access point receives signals in a second frequency band.
 13. The apparatus of claim 11 further comprising a time-of-arrival processor that generates a time stamp for the received signal.
 14. The apparatus of claim 11 wherein said time-of-arrival processor is operative for processing time-of-arrival information when said apparatus is part of a geometric array of networked nodes and determining first-to-arrive signals based on a common network timing signal and conducting differentiation of the first-to-arrive signals to locate a desired wireless node.
 15. The apparatus of claim 11 wherein the real time location system receiver comprises an active antenna system of the wireless local area network access point.
 16. The apparatus of claim 15 wherein the active antenna system is configured in place of a passive antenna.
 17. (canceled)
 18. (canceled)
 19. (canceled)
 20. (canceled)
 21. A method of communicating within a wireless local area network comprising, receiving, at a real time location system receiver, wireless signals transmitted from mobile nodes within the wireless local area network; processing, by a processor of the real time location system receiver, the received signals to obtain message data and signal metrics, the message data and signal metrics including time-of-arrival information; and transmitting, by a wireless local area network access point, the message data and signal metrics to a server in the wireless local area network; wherein the real time location system receiver and wireless local area network access point are comprised in a same device.
 22. The method of claim 21 wherein signals are received in multiple frequency bands and the real time location system receiver receives signals in at least a first frequency band and the wireless local area network access point receives signals in a second frequency band.
 23. The method of claim 21 further comprising generating a time stamp for the received signal.
 24. The method of claim 23 further comprises processing time-of-arrival information and determining a first-to-arrive signal based on a common timing signal and conducting differentiation of the first-to-arrive signals to locate a desired wireless node.
 25. The method of claim 21 wherein the real time location system receiver comprises an active antenna system of the wireless local area network access point.
 26. The method of to claim 25 wherein the active antenna system is configured in place of a passive antenna. 